Departmental program analyzer machine



14, 1956 R. H. LAZINSKI 2,758,786

DEPARTMENTAL PROGRAM ANALYZER MACHINE Filed Jan. 3, I951 15 Sheets-Sheet 1 Dj INVENTOR. 78 I: v RAYMOND H. LAZlN-SKI FIG. 1a. HIS ATTOR EY Aug. 14, 1956 R. H. LAZINSKI 2,758,786

DEPARTMENTAL PROGRAM ANALYZER MACHINE Filed Jan, 5, 1951 15 sheets-sheet 2 27 3; 39 I 26 {2e 52 34 59 40 J L j -4 A JNVENTOR.

RAYMOND H. LAZIN SKI HIS ATTO NE g 14, 1955 R. H. LAZINSKI v 2,758,786

DEPARTMENTAL PROGRAM ANALYZER MACHINE Filed Jan. 3, 1951 15 Sheets-Sheet 5 GO I INVENTOR. RAYMOND H. LAZIN SKI ms A/TTO 2mm 1956 R. H. LAZINSKI 2,758,786

DEPARTMENTAL PROGRAM ANALYZER MACHINE HIS ATTO NEY Aug. 14, 1956 R. H. LAZINSK! 2,758,786

DEPARTMENTAL PROGRAM ANALYZER MACHINE HIS ATT may Aug. 14, 1956 Filed Jan. 3, 1951 R. H. LAZINSKI DEPARTMENTAL PROGRAM ANALYZER MACHINE 15 Sheets-Sheet 7 CARRIAGE RETURN FIG.

FIG.

FIG. ll

INVENTOR.

RAYMOND H. LAZINSKI Y B HIS ATT RNEY l5 Sheets-Sheet 8 Filed Jan. 3, 1951 INVEN TOR.

RAYMOND HQ LAZINSKII BY 9 HIS AT RNE - Aug. 14, 1956 R. H. LAZINSKI DEPARTMENTAL PROGRAM ANALYZER MACHINE 15 Sheets-Sheet 9 Filed Jan. 3, 1951 LQOI 9 0; "mm Nah? R o m T WA E mini $31 whim. E E ot m 6 Q QE 9. HE 2? w 3-x N m v-1 in; $3 swim o 502 E6 Hmm 93. m1 SI E 27m RAYMOND H. LAZINSKI HIS AT ORNEY Aug. 14, 1956 R. H. LAZINSKI 2,758,786

DEPARTMENTAL PROGRAM ANALYZER MACHINE Filed Jan. 3, 1951 l5 Sheets-Sheet l0 Tm: umT LINES PUNCHES PlO,H,l2,|5,|6,l7 33 35 INVENTOR.

36,47,48,49 5 RAYMOND H. LAZINSKI FIGIBIO f zg HIS ATT Aug. 14, 1956 R. H. LAZINSKI 2,758,786

DEPARTMENTAL PROGRAM ANALYZER MACHINE Filed Jan. 3, 1951 15 SheetsSheet 11 RT-P3 RT- P3b RT-P3 R-4b RT-E4b. RT- E4 M A R-24 59 2 PUNCHES ENTO P-IO,|2,I5,|7,24,29, 4

35 3 37 47 4 49, RAYMOND H. LAZINSKI HIS ATTO NEY 5 1955 R. H. LAZINSKI 2,758,786

DEPARTMENTAL PROGRAM ANALYZER MACHINE Filed Jan. 3, 1951 15 Sheets-Sheet 12 PUNCHES' IN V EN TOR. P8,||,l3,l5,24,29,

3,2,37,39,47,? IRAYMOND H. LAZINSKI ,49,5o,s|,54, FIG. l5c! ms ATTO NEY 4, 1956 R. H. LAZINSKI 2,758,786

DEPARTMENTAL PROGRAM ANALYZER MACHINE Filed Jan. 3, I951 15 Sheets-Sheet 13 l l 5 l 5 O I I85 I90 95 200 205-,

PUNCi-ES I P- 8,l |,12 ,|3,|s,17,3s,36, INVENTOR.

RAYMOND H. LAZI'NSKI ms ATTORZEY.

Ffl 6.136

Aug. 14, 1956 R H, LAZlNSKI 2,758,786

DEPARTMENTAL PROGRAM ANALYZEZR MACHINE Filed Jan. 5, 1951 15 Sheets-Sheet 14 INVENTOR.

RAYMOND H. LAZINSKI BY FIG. 13+" 6G HIS AT T RNEY 1956 R. H. LAZINSKI DEPARTMENTAL PROGRAM ANALYZER MACHINE l5 Sheets-Sheet 15 Filed Jan. 3. 1951 INVENTOK. RAYMOND H. LAZINSKI BY 67% HIS ATTORNE United States Patent DEPARTMENTAL PROGRAM ANALYZER MACHINE Raymond H. Lazinski, New York, N. Y.

Application January 3, 1951, Serial No. 204,201

3 Claims. (Cl. 23 -61) This invention relates, in general, to calculating machines. The object of this invention is to provide a programming machine which will produce consistent programs indicating to a registrant the time he will spend in class, the section designation and code number of the sections which in combination formulate each individual program, taking into account as criteria for consistency that no two sections meeting at the same time are included in one program, that no closed section is included in any program, that no section that meets at a time designated by the registrant as free time is included in any program, and that one section from each subject (designated as necessary for the production of a program) is included in each program.

The invention contemplates a free time input circuit, a subject assignment circuit, a punch circuit, a plurality of card punches, a plurality of selector banks, a card reader, a card printer, a card ejection mechanism, and a control circuit.

The invention will be further described, embodiments shown in the drawings, and the invention will be finally brought out in the claims.

In many large concerns it is necessary to program different operations on one object with no two operations being performed at the same time. In large institutions it is necessary to make departmental appointments making sure that the individual is routed to the proper departments, he has not two appointments to be at two difierent places at the same time and that too many people are not assigned to one department at one time. In institutions of higher learning it is necessary that a program of classes be worked out prior to the start of the semester.

A few definitions would be apropos. A course is the name of a general area of learning; such areas are History, Philosophy, Physics, etc. A subdivision of a course would be a subject. Examples are Early European History, Modern European History, American History, etc. A subdivision of a subject is a section. A section is a class, a group of individuals that meet at certain times and places during the week to study the subject. All sections of a subject cover the same material but they meet at different times and places during the week. Free time is the time during which the student has no classes programmed. A filled section or closed section is a section that has its maximum number of students enrolled for it. In the programming of a student for classes four conditions must be met for the formulation of a consistent program.

1. No two classes meeting at the same time during any part of the week are selected for one program. If this precaution were not taken the student would be required to be in two different places at the same time during part of the week.

2. No classes are assigned that meet when the student wishes to be free.

3. No classes are assigned to the student that have been previously filled or closed.

4. A subject selected is represented in each program.

It is required of the student to handle the following information in the formulation of a program.

a. The subjects needed and/ or desired for the formulation of the program.

I). The times of meeting of all the sections of the above mentioned subjects.

0. The times the student wishes to be free and The sections which are available. The latter keeps changing with time as the sections are filled while registration proceeds.

The departmental program analyzer herein described will perform the programming procedure heretofore required in the above example. The description of this machine, the departmental program analyzer, in this case will illustrate its use in the latter example, that of programming students for classes in institutions of learning. The machine will receive information in the form of cards with coded holes punched in them and in the form of the machines buttons being pressed. By pressing the appropriate buttons the student can indicate what periods during the week he wishes to be free and what subjects he needs and/ or wants. The machine, once started, will produce all possible or a preset number of program cards indicating:

1. What time of the Week he will spend in class. 2. What sections to register for and 3. The code numbers of the sections of that program.

The student will then choose the most desirable of these program cards and insert it into a receiving slot. Upon the pressing of a record button the student is tallied, that is, counters indicate that one more student has been added to each of the sections entered on the card. The counters are preset before registration or set during registration by the registrar thus limiting the number of students assigned to one section. Upon that number of students being assigned to one section the machine will automatically take that information into account and will produce no more programs containing that section. A lamp will light indicating that the section is closed. If a program that contains in its program a section that is already closed is inserted into the card reading slot an alarm will ring, the card reading process will stop and lamps will light indicating which section is at fault. All programs produced will meet the four heretofore mentioned prerequisites for a consistent program. Upon selecting the most desirable program card of the number produced for that student the rest are discarded. Upon the machines reading of the program the section designations of that program will be printed on a master form. Other objects of the invention will be pointed out in the following description and claims and illustrated in the accompanying drawings, which disclose by way of example, the best mode, which has been contemplated in applying that principle.

In the drawings:

Figures 1a and lb together constitute the circuit diagram of the selector banks and control circuits.

Figure 2 is a circuit showing the card counter mechanism and a portion of the card punching circuit.

Figure 3 represents the free time selection circuit.

Figure 4 is a circuit diagram of a portion of the permanent relay memory and a portion of the group assignment circuit.

Figure 5 is a circuit diagram of the subject selection circuit which is a portion of the subject assignment circuit. Figure 6 is a diagram of an unpunched program card.

Figure 7 shows the relative position of the punch bars in relation to the outline of the card shown in Fig. 6.

Figure 8 is a fragmentary circuit of the punch circuit.

Figure 9 is an outside elevation of the punch mechanism.

arssyzss Figure 10 is a fragmentary circuit of the section printing circuit.

Figure 11 is a chart showing the manner in which the figures of the circuit diagram of the selector banks are arranged.

Figure 12 is the circuit of the card reading portion of the machine.

Figures 13a to 13h placed in the order named from left to right constitute a sequence diagram showing the order in which the more important relays and other current responsive devices are energized and the periods which they are maintained in energized condition.

Similar characters of reference indicate corresponding parts throughout the various views.

CIRCUIT DIAGRAM In the circuit, the relays are shown adjacent to their related contacts; but in numerous instances, to avoid confusing extension of wires, the release magnets for locking relays (RL) are not usually shown adjacent to magnet are denoted by the letter A or B, following the number of the punch. This can be seen in Figure 8.

It will be assumed that all relays, release coils, stepping switch magnets, counter magnets, punch magnets, bulbs and alarms have the same working voltage. The symbol D. C. will indicate a connection to the common positive terminal of a direct current voltage source, producing the aforesaid working potential. All ground symbols will indicate a connection to the common negative terminal of this voltage source. All potentials hereafter mentioned will be with reference to the common negative terminal of the voltage source. In all cases the relay, stepping switch and punch armatures are shown in the position they retain when their respective magnets are not energized. In the case of locking relays, they are shown in their unlocked position; buttons are shown in their normal, undepressed position.

In this machine, there are many circuit units which have identical wiring diagrams; in all such cases only one of each such circuit unit is shown, the description indicating their means of interconnection.

' The circuit diagram of the selector banks extends through a number of figures which, when arranged in the order shown in Figure 11, constitute the complete wiring arrangement of the selector bank portion of the circuit. As the number of selector banks used depends on the problem to be solved, Figure 11 denotes an undetermined number of banks between Figure la and Figure 2. It will be noted that the circuit diagramsfor all the selector banks are denoted by the number 1, followed by the letter of the bank. All the selector banks but a have the same circuit diagram as shown in Figure lb. The circuit diagram for bank a is shown in Figure la. As all the selector banks have identical parts, the denotation for a part or wire in any bank will be the number of the part shown in Figure lb, followed by the letter designation of the bank in which the part or wire referred to is contained.

The following notations will be used in the description and diagrams of this machine:

Rrelay RL-locking relay TUL--Time unit line CL-closed section line RCrelease coil of locking relay Ppunch armature magnet SW--Switch (toggle) B-push button L-lamp bulb W-wafer of rotary switch C-contact, of rotary switch or relay Mmagnet operating stepping switch RSWrotary switch RTtime memory relay RNnumber memory relay ROTARY SWITCHES AND COUNTERS In this machine there are two types of automatic stepping switches used. The type hereafter referred to as type a is a spring driven, telephone type automatic stepping switch with interrupter contacts attached. Such a switch is shown in Fig. 1b. It is composed of parts W1, W2, W3, W4, W5, Mb, 4, 6, 1, 3, 2, 7, 31 and 5. When the stepping switch. magnet Mb is energized, the armature 1, which is pivoted at 4, is attracted to Mb, causing pawl 2, which is pivoted at 3, to engage the next tooth of the ratchet wheel 7. The accompanying diagrams are simplified for ease of comprehension; only three contacts per wafer are shown in Fig. lb and, therefore, only 3 ratchet wheel teeth are shown. in an actual switch, there would be many more teeth, allowing a small movement of the pawl to engage the next tooth. Upon the de-energization of Mb, armature 1 and pawl 2 are returned to their normal positions by means of a spring (not shown) connected to the armature; thus causing the ratchet wheel 7 to move the common shaft 31 a portion of a clockwise revolution, one step. As the contact arms of wafers W1W5 are attached to the shaft 31, without allowing an electrical path through the shaft between any of the contact arms or ratchet wheel 7, all the contact arms of their respective wafers will also rotate a portion of a revolution to the next contact on their respective wafers. Each time Mb is energized and then de-energized, the contact arms will move to the next contact on their respective wafers.

Retrograde rotation of the ratchet wheel is prevented by the check pawl 5. Contact 6, in conjunction with armature 1, acts as an interrupter. When a potential is applied to 6, current flows through Mb, attracting armature 1, the movement of which breaks the contact 1, 6. The magnet is de-energized, causing 1 to return to 6. This causes a reciprocatory motion to be imparted to pawl 2. The action of the armature 1, in this case, is very similar to the action of the armature of a household buzzer. The inertia of the armature 1 and pawl 2, and the adjustment of the contact 6 and 1 are such that every time 1 is attracted to Mb, pawl 2 engages the next tooth of the ratchet wheel 7. Upon the return of 1 to its normal position, it carries the shaft 31 and ratchet wheel 7 another portion of a revolution clockwise. When armature 1 returns to its normal position, the contact 6, 1 is made, causing the magnet Mb to be energized. This causes the switch to step to the next position. Thus, by applying a potential to 6, the pawl 2 will be caused to reciprocate, causing the rotary switch to continue to step until this potential is removed from contact 6.

The other type of stepping switch used in this machine will be denoted type b. Qne of those switches is shown on the right side of Fig. 2. The stepping action of this type of switch is very similar to that of type a, but in this case, the ratchet wheel 12 is stepped when the Magnet MA is energized (magnet driven) and not as in type a, when the magnet is de-e'nergized. When MA is energized, armature 8 which is pivoted at 9 is attracted to MA causing pawl 10 which is pivoted at 1 1 to engage the tooth directly below it on ratchet wheel 12 causing the wheel to make one step in a counterclockwise direction. As knob 13 and contact arm 14 are connected to the same shaft 17, as is the ratchet wheel 12, they too are caused to make a partial rotation. This their respective contacts .C-2.

arse-ass :type of-swirtch also acts as .a counter. The knob 13 will indicate on the stationary dia191 how many more :steps the .switch has to take before the contactarm comes in contact with the :first contact on the wafer, in this case the contactconnected to wire 61.

The normal position of armature 8 and pawl 11 are such that they remain out of the way of the ratchet wheel teeth. The armature is held in the upper position by a spring (not shown). This enables the knob 13 to be turned 'by hand, causing 17, 12, and 14 to rotate with it enabling the counter to .be set by hand. This determines how many times MAhas to be energized and tie-energized before the circuit 14, 61 is completed. The ball 1'5 is held against the ratchet wheel 12 by spring 16 in such .a way as to allow the ratchet wheel to be rotated in a counter-clockwise direction by the stepping mechanism or to be rotated in either direction by the knob 13. The diameter of the 'ball 15 should be greater than the .depth of a ratchet tooth, so that the ball does not jam against the to'ot'hs surface. n'ism allows for only discrete steps of .the switch. Therefore, the knob 13 will always point directly at a numher on dial 91 after the switch has been stepped.

This type of rotary switch acts as a resettable counter which closes a contact upon reaching the zero position.

On some portions of this circuit, the counter will have as its final position a minus one position, .so that it will close another circuit when the magnet 'is energized after the counter has reached zero position. Such switches can be seen in Fig. 4.

OPERATION OF SELECTOR BANK in Fig. lb ,it will vbe noted that when 'R-1, R-2 and .R-B (the contacts of which may :be on one relay, are

shown here as three relays for .ease in circuit comprehension.) whose coils-connected in parallel with L-1 are urn-energized, the paths of wires 18 .and 19 at the left are made through 2.0 and .21 out to the right through the contacts of R-.2 and .out through the wire 22 and 23, respectively. Only when these relays are energized does the selector bank play any part in the operation of the machine. When R4, R-2, and R-3 are not energized, the bank is said to be inoperative and acts as if it were not connected in the machine .circuit. Whenapotential is applied to 62, relays IR-rl, R-2, and,R-3 are .energized and -.L-l on a panel is lit indicating that the bank .is operative. When a bank is inoperative, sits rotary'switch and W-S will be in the normal position, contact arms touching (3-1, as in W--1. To cause the bank -;to be operative, a potential is applied to '62 and RT and R-N relays are assigned to the bank. They are connected .as shownin Fig. lb.

Agpotential on 18 appears-on the contact arm of W-l, energizing relay RT-l, causing the potential on :wire .24 to appear on wire .25, energizing R-4, simultaneously the input wires to RT-1, .26, 27, and 28., to be called RT input lines are connected to C-1 of W-2 through wire 35 to 29. At this point, the selector bank can act in tone of two modes of operation. One mode will .occur if there is .a potential on any of the RT input :lines'of .the RT relay energized and the other mode .will occur if there is no potential on any of .the RT input lines upon the energizing of the associated RT relay. The former mode will .be assumed.

Upon the energizationof -RT.1, a potential will appear on .35 and 29. This will cause a current to fiow through the wire 35, C-1 of W-Z, 29, through the upper arm of 11-5 through interrupter contact 6, through 1 to Mb and to ground, therefore energizing Mb causing the rotary switch type a, to take a step, switch operation heretofore described, moving all the contacts -of the associated wafers to their next clockwise position, .to Upon reaching 0-2 the contact arm of W-l which still has a potential on it The ball and spring mechabank will start operating.

would now cause RT-2 to be energized. tkelay .dcfenergizcd when the contactarm tmoyedifrom to C.2. When the contact arms of RT-.2 .are.closed,-the RT input lines of RT-2 are .connected through wire 37 to wire 29, at this point either :of .the two modes of operation will :-take place, depending upon whether .or not there .is a potential on any .of .the tinput -lines .of RT2. It must .be noted that R-4 was de energizedfor an interval when the contact arm of W-l was .moving from 0-1 to C42. The :RT and R- -5 {relays are ,fast opening and fast closing relays, While R4 is a .slow closing and fast-opening relay. When R-Ais energized, upon closing, it energizes R-.5. Upon the stepping of the rotary switch, .the RT relay must be .uneenergized, R-dopen, and 11-5 open in the time it takes the contact arm at W1 to move from one contact to thenext. Should there be a potential on an RT inputsline, the rotary switch will have an opportunity to step upon the closing of the contacts of the RT relay before the.contact arm of R-4 is ,closedand tthc Upp r arm-,of.R.5.is swung down, disconnecting wire .29 from contactfi. indicates the need for a .slow closing and fast opening relay R-4.

The second mode of operation .of the selector bank will now be assumed, no potentiahon the RTinputalines. Starting from its .normal position, with -the contactarms .on contacts .C-l; when the :rotary switch is .in this position, the bank is said to be zeroed. We will assume the bank is zeroed, apotentialis appliedto .1'8 and the bank .is ioperative.

A potential :appears on the contact arm .of W-l ,and 63 .causing R1 1 to be energized connecting 26, 2'7, and 28 to be connected with 35 and 29. .A potential from 24 causes R4 to be energized on the closing of the contacts of RT:1. As thereiis -zno poten- :tial on 29 now, the rotary .switch does not step, .R-4

has time to close, energizing "R 5. When R5 isenerto 18 of the'bank 1c; therefore, if'bank -1c-is operative,

a potential will appear on the arm of W-flt' and that This action at R5 being energized and remaining that way applying a potential to 22 is called settling down. -The arm of W-S is connected to the D. C. positive terminal. Therefore, when the bank settles down on a contact a potential "will appear on one of the section indicating lines, P-32,

-P-36, or F40. The associated RN relay will connect the bank is zeroed and inoperative; therefore none of the P associated with'thebank will be connected to wire 43 or have a potential on them, when the bank is inoperative and zeroed. Afiter the bank has settled down the only Way to cause the rotary switch ,to step is "to apply a voltage ,to point 4, at point 23 ifthe "bank is operative, or at 77. Should it be desired .to set the rotary switch to the normal zeroed position it wouldbe necessary only to applya voltage to wire 47. lfthecontact arm of W-3 is not on contact 1, it will connect '6 through a rectifier 48 to the voltage source, thus causing the switch the keep stepping until the arm of W-3 was on C-l, thus removing the potential from point 6. This stops the switch at the zeroed position. Rectifier 48 prevents any fiow of current from 6 into wire 47 so that the selection operation of one bank does not interfere with other banks selection as .they all have ,a.comn1o.n wire 47. This makes it possible to have the :banks act ,relay R-'1, R2, and R3 also lighting LI.

independently and still have a common zeroing line. It is necessary that this potential remain on 47 until the bank returns to the zeroed position. When a potential appears on 47 of one bank, it appears on 47 of all the banks and the potential must remain there until all the banks are zeroed. It will be noted that R-6 is energized and L-2 is lit, only when the bank is zeroed. Therefore, the control circuits explained hereafter will keep a potential on 47 as long as there is any direct connection between wires 49 and 5h through any relay R6. All the banks would have to be zeroed before all the R6 relays were energized and therefore would leave no direct path between 49 and 50. Then and only then will the potential be removed from 47, this is the method used in resetting all the selector banks of the machine.

enables the banks to investigate all possible combinations of RT relays without potentials on their RT input lines.

The selector banks act like the mechanical counter Wheels of the type used as a mileage indicator in an automobile speedometer. For every rotation of the rotary switch of a bank, the bank adjacent to it, to the left, makes a step to the next RT relay with no potential on its RT input lines.

THE SELECTOR BANK CONTROL CIRCUITS The control circuits Fig. 1a contain buttons and i switches which control the startin stopping, the continnation after stopping, and the ct circuits of the inn-- chine. The selector bank portion of this circuit acts exactly like that of the selector bank 12 with the exception that there is one more position, contact, CO, on

each wafer of the spring drive type a rotary switch than there are on the other selector bank rotary switches. In this diagram the RT and RN relays are not shown, but they are connected in the same manner as shown in Fig. lb. This bank is zeroed when the contact arms are on CO; at this position R6a is energized, the lower arm of which serves the same purpose as the arm of relay R6b, opening a path between wires 49 and 50. In bank a when rotary switch 1a is zeroed, L-Z indicates on a panel that the bank is zeroed and. Ll indicated whether the bank is occupied or not. In assigning the RT and RN memory relays to each bank one group is connected (by a circuit explained hereafter with the aid of the circuits shown in Figs. 4 and 5) to bank a, the next to bank b, the next to bank 6 and so on. As each bank is assigned a group of RT and RN relays, a potential is applied to its contact 62, energizing its The machine would not function unless at least one bank was assigned a group of RT and RN relays. Since the RT and RN relays are assigned in the order of bank rotation, to a, then to b, the third to c and so if only one group is assigned by the switching circuits of Figs. 4 and 5 will be assigned to bank a. Therefore, there is no reason to have any relays such as Rll, R2 and R3 as banka would always be operative.

It was stated in the description of the operation of bank 112 that only when a potential appeared on 13 of the bank will it operate. This happens when the previous bank settles down, in the case of bank a, there are no previous operating banks. Bank a would be the first to start operating, therefore the contact arm of W-1 is connected directly to wire 42 instead of going through a con-tact of a R-S relay to Wire 42. This arrangement allows bank a to operate immediately upon the starting of the machine. Before the machine is started, it is necessary that certain conditions be met. The proper RT and RN relays must have been assigned to the various selector banks; those banks assigned RN and RT relays must have a potential placed on their respective 62 contacts, and a potential must appear on all wires 42.

STARTING To start the machine a potential is applied to Ma for a short time by means of applying a voltage to 67 and R7 simultaneously by depressing B-1, the start button. It will be noted that a potential from 68 appears on 69 only when R6 is energized; this only happens when bank a is zeroed. Since R7 attracts the armature of R7, a slow closing relay, a short time after R-7 is energized the circuit 66, 67 is broken, shortly after 3-1 is depressed sending only a short pulse of current through M-a. Rectifier 65 prevents R7 from being energized every time Ma is energized in the normal operation of the selector bank. Now that this bank has stepped one step from its zeroed position, the contact arm at W-1a is on C1 energizing the RT- la thus causing the selector switch to start its search for a contact which is connected to a RT relay with no potential on its RT input lines.

Upon the settling down of the first bank, a potential will be applied to 18 of the next bank and that bank will search until it finds a contact connected to an RT relay with no potential on its RT input line. Upon finding that RT relay, the bank will settle down, causing the next bank to operate and so on until all the operative banks have settled down, causing a voltage to be applied to wire 22 of the last operative bank. This will apply a potential to wire 51 (see Figs. lb, 2, and 11). This searching process would continue until the potential is removed from wire 42. If the potential was removed from wire 42, all the energized RT relays would be deenergized and all selection would stop. Upon the application of this potential to 42, the process would continue from where it had left off when the potential on 42 was removed. It will be seen in Fig. 1a that 42 is connected to the potential source 68 through the lower contact of Rfi, therefore when R8 is energized, the circuit 68, 42 will be broken and the machine will stop. When RS is de-energized, the machine will continue from where it left off. When the stop button B2 is pressed, a circuit is made from 68 to 70 causing current to flow through the coil of relay Rfi, if Rltl is un energized, to ground. This causes the arms of R8 to swing down, breaking the circuit 68, 42 while making the circuit 63, 70 through the upper arm of R8. This causes the relay R8 to remain energized even after B2 is released. As L-3 is in parallel with R-S it will light, thus indicating that the machine has stopped operation. By depressing and releasing B2, the machine will stop and remain stopped until R-10 is energized. The circuit 68, 70 can be made by either 13-2 or by R9.

CONTINUING When Rlil is energized for a short while, the holding circuit of R8 is broken and the arms at RS will swing up and remain up, applying a potential to 42 allowing the machine to continue its operation from where it left oif. If R18 is not energized the pressing of B3 will apply a potential to 72, 71 and thus energize R-10. If R18 is energized, the pressing of B3 will put a potential on 72 causing a chime 73 to sound. This chime will sound as a warning that the machine is not supposed to continue. There are two conditions in which this will happen.

One condition is that the machine has investigated all possible combinations of RT relays without potentials on their RT input lines, meaning that rotary switch has returned to its normal position, energizing R-6a, its middle contact arm making circuit 68, 78 through R18.

RESETTING By depressing E4, the reset button, or by energizing R-12 a potential is applied to 49. If any of the R-6 relays are not energized, meaning that their respective banks are not zeroed, then a potential will appear on 50 energizing R-13 causing the circuit 68, 49 to be made through the lower arm of R13. Therefore, if the circuit 68, 49 is made by R12 or by E4, the relay R-13 will remain closed as long as an R-6 relay is un-energized, making a direct path between 49 and 50. While R13 is energized potential appears on 47 through the upper arm of R-13 from the potential source 68. The potential on 47 cause the resetting indicator to light, and thus as described in the operation of selector bank b, the banks are caused to step until they reach their zeroed positions. Upon reaching their respective zeroed positions, their R6 relays are energized. The circuit 49, 50 is broken when all R-6 relays are energized, R-13 is thus de-energized, the potential being removed from 47. The potential will not return to 47 until B-4 is pressed or R-12 is energized for a time long enough to let the contacts of R13 close. If a potential should appear on wire 61, it will cause a potential to appear on 75 until R44 is energized. R-14 will not be energized until R-15, then R-16 are energized. This is longer than the time taken for R8 to be energized and remain energized by its self energizing circuit 68, 70. Thus a potential appearing on 61 will cause the machine to stop. If SW-l is closed, R12 will be energized long enough to allow R13 to self energize through the circuit 68, 49, 50, causing the machine to reset. When SW-l is open, the machine will stop when a potential is placed on 61. When SW-l is closed, the machine will stop and reset when a potential is applied to 61. We then call the position or" SW1 when open the automatic stop position and when closed the automatic stop and reset position. A potential will appear on 86 for a short while upon an application of potential to 61 if SW-2 is closed, causing the memory circuits, discussed later (see Figs. 4 and 5) to be reset. Rectifier 74 is used to prevent the circuits, in conjunction with wire 86, from causing the machine to stop. When a potential appears on wire 61, either from 14 (see Fig. 2), or R-6.a, it not only energizes R18 as discussed in the description of the Continue circuit, but also energizes R through wire 75 causing a potential to appear on R-9 etc. as just discussed. R-15, a slow closing relay, causes R-16 to be energized then causing the circuit 61, 76, the R-14 self energizing circuit, to be made through the lower arm of R14 at the same time removing the potential from 75. The arms of R14 swing down before R-16 opens, due to the delay caused in the opening of the contacts of R-15 and R-16. It can be seen that a potential appears on 75 only during the time it took for R-15 and R-16 to close. This time is longer than it takes R-9 to cause R-S to self-energize and longer than it takes R-12 to cause R-13 to self-energize. The machine can be made to stop and reset after a certain number of energizations of MA (Fig. 2) if SW-3 is closed. The machine can be made to stop and reset when the RSWla returns to its zero position after exploring all the combinations of RT relays without potentials on any of their respective RT input lines. Should all possible combinations of RT relays without potential on any of their RT input lines he desired, and this number of combinations should exceed the capacity of the counter shown in Figure 2, the SW-3 is opened so that no potential appears on 61, even though the counter returns to the zeroed position. Therefore, the machine will not stop and reset until RSW-a returns to its zeroed position.

to PUNCH AND PROGRAM COUNTER crncurrs (Fig. 2

When bank a settles down, a potential appears on 41a, 18b causing bank b to search, upon thesettling down at bank b a potential appears on 41b causing the next bank to operate. This continues until all the operative banks have settled down. Upon the last bank settling down, a voltage appears on its wires 41 and 22 which causes a voltage to appear on wire 51 of Fig. 2. When a potential appears on wire 51, it also appears on wire 52. As R-19 is un-energized, this causes R-11 to be energized and sends a current along wire 53 which is connected to wire 82 of R-24 (Fig. 8) causing R-24 to be energized. R-11 and R-23 are slow closing relays. Thus, by the time R11 causes its contact to close causing R-23 to be energized, causing its contact to close energizing R-l9 and breaking the 51, 52 contact; R24

had time to cause all its contacts to close, grounding all the B wires of the punch magnets from P-1 to P46 at the same time a potential is applied to wire 43, thus energizing any of the punch magnets P-47 through P-62 that are connected to wire 43 through the contact arms of the RN relays; the B wire at punch magnets P-47 through P-62 are connected directly to ground as illustrated by P-56 (Fig. 8) upon the energization of the punch magnets the punch armature 92 of Fig. 9 is attracted downward, pivoting at 97, causing the punch rod 93 pivoted at 98 to punch a hole in the card (Fig. 6) which would be in the space between the rod guide 94 and the die 95. The potential remains on 53 long enough for the punches to operate, the delay caused by the successive closing of R-11 and R-23, upon the energization of R19 the potential would be removed from 53, the punch magnets would be de-energized and the spring 96 would cause the punch armature and punch rod to return to their normal positions against the adjustable stop screw of the punch frame 99. When the relay R19 is energized the circuit 51 to 58 is made by the lower arm of R-19, before the arm of R-23 has time to break its contact thus applying a potential to R-19 through the lower arm of R-19 causing R-19 to remain energized as long as a potential remains on 51. Upon the energization of R-19, MA is energized by a current flowing through 51 and 57. This causes the rotary switch to step one step, as described in the description of type b rotary switch at the same time causing a potential to be applied to 59. 59 is a mechanism that removes the card (Fig. 6) from between the rod guides 94 and die of Fig. 9 and replaces by another card, unpunched. Such a mechanism may be a Geneva wheel geared to wheels 100, 101, 102 and 103 of Fig. 9 by means of a magnetically operated clutch which enables the Geneva wheel to cause the wheels 100, 101, 102 and 103 to turn enough to remove one card from the punching space between 94 and 45, and replace it by an unpunched card. Upon the removal of the punched card and the positioning of a new one, the wheels 100, 101, 102 and 103 stop the last selector bank from affecting the circuit of Fig. 2.

When the potential appears on 56, which is connected to 23 of the last operative bank, the rotary switch of that bank is caused to be stepped and the search for a contact associated with an RT relay which has no potential on its RT input lines is continued. The time of return to their normal position of R-19, R-ll, R-23 and MA should be less than the time taken by the last selector bank to settle down on its very next contact. It can now be seen that a potential does not appear on 51, until all the operative selector banks have settled down. When this happens a card is punched, ejected. 

